Abstract
This paper focuses on modelling, control, realisation and performance analysis of a full-scale demonstrator for a novel railway track switch. For over a century, railway track switches (or points) have been allowing trains to safely change between routes. As they are safety-critical elements of the rail network, when they fail, the signalling system will prevent trains from using that route. This means poor reliability (or lack of availability) leads to significant delays and costs; hence there is huge interest from researchers and engineers in improving the overall reliability of track switches. This paper presents new results, which represent a meaningful first step toward a revolution in the way track switches are actuated. A “REPOINT-Light” railway track switch demonstrator is introduced which uses a new concept of locking to allow redundant actuation with three actuator bearers operating under closed-loop feedback control. The new concept, its control system and its mechanical viability are tested in experiments at the Great Central Railway in the UK. To support the design of the actuators and the control system, a dynamic simulation model is developed by co-simulation involving Simulink and Simpack. The experimental results presented are used to validate the models and the paper discusses how the models themselves are used as the vehicle for the design of feedback controllers. Virtual testing of the controllers in simulation is a vital step prior to the implementation and deployment of the controllers in the demonstrator switch. The major contribution of this work is demonstrating, for the first time at full scale on a real-world track switch, that it is possible to use one-out-of-three actuator redundancy to provide fault-tolerant operation of railway track switch.
Highlights
The railway track switch system, which allows trains to change between routes, is a safety-critical part of the rail network
The work presented in this paper summarises the process, modelling, control design and experimental outcomes of the first full-scale application in a real railway environment of the REPOINT-Light concept
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Summary
The railway track switch system, which allows trains to change between routes, is a safety-critical part of the rail network. The two switch rails are connected by a stretcher bar and driven from a single actuation force while switching [1], and are secured in place (once switched) with a mechanically operated lock. These systems are prone to failure and any failure of the switch system causes delay and occasionally catastrophic derailment as happened recently in the US where two people were killed and injured ninety others [2]. The results, presented in this paper, represent the worlds-first and only set of full-scale experimental results from a number of radical approaches to track-switching that have been proposed over the past decade
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